What makes a leaf to be efficient in photosynthesis?
Answers
the presence of chloroplast
The energy efficiency of the photosynthesis is the ratio of energy stored in the energy of the absorbed light. The chemical energy deposited is the variance amongst gaseous oxygen and organic compound products and energy of water, carbon dioxide and other reactions. The amount of stored energy can be estimated because many products are formed, and they are different with plant species and environmental conditions. If the equation for the given glucose formation is used to estimate the actual storage process, then production of one mole of oxygen (i.e. 6.02 × 1023 molecules, in brief) and the sixth hole of glucose resulted in approximately 117 kilocalories (KKC) of chemical energy. To calculate the efficiency of photosynthesis, this amount should then be compared with the energy of the absorbed light to produce a sesame of oxygen.
Light can be described as a wave of particles known as photons; These are energy units, or are light quanta. Quantity n photon is called Einstein. The energy of light varies in contrast with the length of the photon waves; The wavelength is small, the higher the volume of energy. The energy (e) of a photon is given by the equation e = hc / λ, where c is the speed of light, the stability of H plan is, and λ is the light wavelength. Einstein's energy (E) E = is = NHC / λ = 28,600 / λ, when E is in kilocalory and given in λ nanometer (nm; 1 nm = 10-9metres). With the wavelength of 680 nm, red light Einstein has about 42 kilograms of energy. Blue light has less wavelength and therefore more energy than red light. Even if the light is blue or red, even if the number of eusteen is required for mole light synthesis towards oxygen. Part of the solar spectrum used by plants is estimated to be 570 nm of the estimated average wavelength; Therefore, the light energy used during photosynthesis is approximately 28,600 / 570, or 50 kg per Einstein.